Related papers: Hierarchy of degenerate stationary states in a boundary-driven dipole-conserving spin chain

Hierarchy of degenerate stationary states in a boundary-driven dipole-conserving spin chain

URL: http://arxiv.org/abs/2411.03309v2
Date: Wed, 19 Feb 2025 09:02:33 GMT
Title: Hierarchy of degenerate stationary states in a boundary-driven dipole-conserving spin chain
Authors: Apoorv Srivastava, Shovan Dutta,
Abstract summary: Kinetically constrained spin chains serve as a prototype for structured ergodicity breaking in isolated quantum systems. We show that such a system exhibits a hierarchy of degenerate steady states when driven by incoherent pump and loss at the boundary.
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Abstract: Kinetically constrained spin chains serve as a prototype for structured ergodicity breaking in isolated quantum systems. We show that such a system exhibits a hierarchy of degenerate steady states when driven by incoherent pump and loss at the boundary. By tuning the relative pump and loss and how local the constraints are, one can stabilize mixed steady states, noiseless subsystems, and various decoherence-free subspaces, all of which preserve large amounts of information. We also find that a dipole-conserving bulk suppresses current in steady state. These exact results based on the flow in Hilbert space hold regardless of the specific Hamiltonian or drive mechanism. Our findings show that a competition of kinetic constraints and local drives can induce different forms of ergodicity breaking in open systems, which should be accessible in quantum simulators.

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